Attachment devices and methods for spinal implants

ABSTRACT

A system for the treatment of a spine generally comprises an implant and an attachment device for securing the implant to a portion of a patient&#39;s bone. A first portion of the attachment device is sized for insertion into a hole in the bone, and a second portion of the attachment device is configured to be received in an opening of the implant. The first portion comprises a biocompatible material defined by a network of interconnected pores configured promote bone growth into the first portion.

FIELD OF THE INVENTION

The present invention relates generally to systems and methods for thetreatment of a spine, and more particularly to systems and methods forsecuring biocompatible implants to a bone of the spine.

BACKGROUND

The spinal column is a highly complex system of bones and connectivetissues that provides support for the body and protects the delicatespinal cord. The spinal column includes a series of vertebrae stackedone on top of the other, each vertebral body including an inner orcentral portion of relatively weak cancellous bone and an outer portionof relatively strong cortical bone. The vertebrae in the cervical,thoracic, and lumbar regions of the spine are separated byintervertebral discs, which serve as cushions between adjacent vertebraeto dampen compressive forces experienced by the spine. A vertebral canalcontaining the spinal cord is formed by the intervertebral foramen ofthe vertebrae.

There are many types of conditions that can lead to significant pain andaffect movement of the spine. Oftentimes these conditions are treated bysecuring or more implants to the spine, with the implants being designedto achieve a particular type of treatment. For instance, facet implantsare often implanted between the facet surfaces of adjacent vertebraewhen it is desired to provide joint spacing, joint stabilization, jointcapsule replacement, cushioning and/or an articulating surface for theopposing pair of facets. Examples of such facet implants are disclosedin U.S. patent application Ser. Nos. 11/221,938 and 11/274,385, whichare owned by the assignee of the present application and herebyincorporated by reference in their entirety. Other implants include,without limitation: cervical plates, fixation rods, and similar devices.

The implants are typically secured to the spine using one or more bonescrews or other attachment members. Other fixation techniques are alsoused when desired. For example, in some applications the implants aresecured using adhesive or sutures. In other applications, the implantsare secured by a post cemented into a cavity created in the bone.Although a wide variety of attachment devices and methods exist, thereremains room for improvement.

SUMMARY

A system for the treatment of a spine generally comprises an implant andan attachment device for securing the implant to a portion of apatient's bone. A first portion of the attachment device is sized forinsertion into a hole in the bone, and a second portion of theattachment device is configured to be received in an opening of theimplant. The first portion comprises a biocompatible material defined bya network of interconnected pores configured to promote bone growth intothe first portion.

In one embodiment, the hole in the bone may be greater in a firstdimension than in a second dimension. The first portion of theattachment device may be rotated when received in the hole to a positionthat restricts removal of the attachment device from the hole.

In another embodiment, the first portion further includes an inner boreextending therethrough, an outer surface, and a plurality of channelseach extending from the outer surface to the inner bore. The channelsprovide fluid communication from the inner bore to the bone for thedelivery of a bone growth promoting material.

In yet another embodiment, the biocompatible material of the firstportion has a degree of porosity that approaches that of the bone. Thebiocompatible material may comprise porous tantalum in some embodiments.

A method of securing an implant to a bone is also provided. The methodgenerally comprises forming a hole in the bone, positioning the implantrelative to the bone so that an opening in the implant is incommunication with the hole in the bone, and a inserting a first portionof an attachment device through the opening of the implant. The firstportion extends into the hole of the bone so that a second portion ofthe attachment device is then received in the opening of the implant.Again, the first portion of the attachment device may comprise abiocompatible material defined by a network of interconnected poresconfigured to promote bone growth into the first portion.

In one embodiment, the hole in the bone is formed with an ellipticalconfiguration having a minor axis, a major axis, and a first dimensionalong the major axis. Additionally, the first portion of the attachmentdevice has an elliptical cross-sectional configuration with a firstdimension approximately equal to the first dimension of the hole in thebone and a second dimension less than the first dimension. Inserting theattachment member in such an embodiment may further comprise insertingthe first portion into the hole in the bone with the first dimensionaligned with the major axis of the hole and the second dimension alignedwith the minor axis of the hole.

The hole in the bone and the first portion of the attachment device maybe formed with matching elliptical configurations in some embodiments sothat the first portion is secured within the hole upon insertion. Inother embodiments, the method may further comprise rotating theattachment member relative to the hole after the first portion isinserted therein. The attachment member may be rotated so that the firstdimension of the first portion is substantially aligned with the minoraxis of the hole and the second dimension of the first portion issubstantially aligned with the major axis of the hole.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute apart of this specification, illustrate exemplary embodiments of theinvention and, together with a general description of the inventiongiven above, and the detailed description given below, serve to explainthe principles of the invention.

FIG. 1 is a perspective view illustrating an exemplary implantpositioned in the facet joint of a spine.

FIG. 2 is a perspective view of an attachment device according to oneembodiment of the invention for securing the implant of FIG. 1 to abone.

FIG. 3 is a cross-sectional view taken along line 3-3 in FIG. 2.

FIG. 4 is a cross-sectional view similar to FIG. 3 showing theattachment device of FIG. 1 inserted into a hole in a bone.

FIGS. 5A and 5B are cross-sectional views illustrating a portion of theattachment device of FIG. 1 being initially secured within a hole in abone.

FIG. 6 is a cross-sectional view illustrating a portion of an attachmentdevice according to another embodiment of the invention secured within ahole in a bone.

FIG. 7 is a perspective view of an attachment device according toalternative embodiment of the invention.

FIG. 8 is a cross-sectional view of the attachment device of FIG. 7secured within a hole in a bone.

FIG. 9 is a perspective view of an attachment device according to yetanother embodiment of the invention.

DETAILED DESCRIPTION

FIG. 1 generally shows one example of an implant 10 that may be used totreat a spinal condition. The implant 10 generally includes a main body12 positioned between opposed facets 14, 16 of adjacent vertebrae 18, 20and fixation wings 24 secured to the vertebrae 18, 20 using one or moreattachment members 26. Such an arrangement provides the implant 10 witha generally T-shaped configuration, with the fixation wings 24 beingbent and/or stretched as needed to conform to each vertebra 18, 20before being secured by the attachment members 26, which extend throughopenings 28 in fixation wings 24. The fixation wings 24 exert aretraining force on the vertebrae 18, 20 to help maintain the opposedfacets 14,16 in a desired orientation. Additional details relating tothe implant 10 are provided in U.S. application Ser. Nos. 11/221,938 and11/274,385, the disclosures of which, as indicated above, are fullyincorporated herein by reference.

Although the implant 10 will be referenced below when discussing detailsof attachment members according to the invention, those skilled in theart will appreciate that the invention may equally apply to anybiocompatible implant secured to bone. For example, attachment membersaccording to the invention may be used to secure plates and othersimilar devices to vertebrae of the spine or other bones in a patient'sbody.

With reference to FIG. 2, an attachment device 40 according to oneembodiment of the invention includes a first portion 42 and a secondportion 44. The second portion 44 may be a separate component mounted onor secured to the first portion 42, or may be integrally formed with thefirst portion 42 such that the attachment device 40 has a one-piececonstruction. The embodiment shown has a two-piece construction with thefirst portion 42 being formed from a porous first material and thesecond portion 44 being formed by a more rigid second material. To thisend, and as set forth in further detail below, the first portion 42 maybe formed from a material designed to promote ingrowth of bone whereasthe second portion 44 may be formed from a material designed tointerface with one of the openings 28 (FIG. 1) in the implant 10.

As shown in FIGS. 2 and 3, the first portion 42 has a generally oval orelliptical cross-sectional profile when viewed in a plane generallytransverse to an axis 45 of the implant 10. Thus, the first portion 42has a first dimension L1 along a major axis 46 (FIG. 5A) and a second,smaller dimension L2 along a minor axis 48 (FIG. 5A). The second portion44 includes a first section 50 having a first radial dimension and aflange section 52 having a second radial dimension larger than the firstradial dimension. The first radial dimension may or may not beapproximately equal to the first dimension L1 of the first portion 42. Afastening section 54 extending from an upper surface 56 of the flangesection 52 is shaped so that the attachment device 40 may be gripped orrotated by a tool (not shown). For example, in one embodiment, thefastening section 54 includes straight edges 58 defining a hexagonalstructure so that the implant 10 may be rotated by a socket wrench orthe like.

The second portion 44 also includes an axial bore 60 extending throughthe fastening section 54, the flange section 52, and the first section50. Although the axial bore 60 is shown as being generally cylindrical,other shapes and configurations are possible. For example, if desired,the axial bore 60 may have a hexagonal configuration so that the implant10 may be rotated with an Allen key (not shown) or similar type of tool.The first portion 42 is provided with an inner bore 62 as well, but theinner bore 62 extends from the axial bore 60 to an outer surface 64 ofthe first portion 42. Thus, the axial bore 60 and inner bore 62 define apassage extending through the implant 10. In one embodiment, the innerbore 62 is generally in the shape of an inverted Y with a first branch66 and a second branch 68 extending to respective first and secondlocations on the outer surface 64. In an alternative embodiment, theinner bore 62 has a substantially T-shaped configuration. In yet anotherembodiment, the inner bore 62 may extend through the entire longitudinalaxis of the attachment device 40.

FIG. 4 illustrates the attachment device 40 securing one of the fixationwings 24 to a vertebra 80, which includes a hard, outer layer ofcortical bone 82 and inner cavities (not shown) of softer cancellousbone 84 (also referred to as trabecular bone). The first portion 42 isreceived in a hole 86 formed in the vertebra 80 and is configured toallow bone growth into portions thereof. To this end, the first portion42 may be constructed from a highly porous material so that thesurrounding cancellous bone 84 is able to rapidly and extensively growinto the interconnected pores to secure the attachment device 40relative to the vertebra 80.

For example, the first portion 42 may be comprised of a biocompatiblematerial having a degree of porosity that approaches that of naturalcancellous bone. One example of such a material is Trabecular Metal™material, which is marketed by Zimmer Spine, Inc., of Edina, Minn. Thismaterial is also described in several U.S. patents, including, forexample, U.S. Pat. Nos. 5,443,515 and 6,063,442, the disclosure of whichare incorporated herein by reference. In addition to having a cellularor highly porous structure that resembles cancellous bone itself, thematerial of the first portion 42 may have a high compressive strengthand low modulus of elasticity comparable to cancellous bone. Because itapproximates the physical and mechanical properties of cancellous bone,the material of the first portion 42 is highly conducive to boneformation. Moreover, the material can be fabricated into complex shapesas needed to match a particular implant or hole.

Although the Trabecular Metal™ material marketed by Zimmer Spine is aporous tantalum material fabricated using a vapor deposition technique,those skilled in the art will appreciate that the first portion 42 mayalternatively be constructed from other biocompatible materials having adegree of porosity similar to that of natural cancellous bone. Theseother materials may include metallic materials (pure metals and/oralloys) other than tantalum, or porous ceramic materials having theappropriate physical and mechanical properties.

When the first portion 42 is received in the hole 86, the first section50 of the second portion 44 is received and positioned in the opening 28of the fixation wing 24. The flange section 52 remains positionedagainst an outer surface 64 of the fixation wing 24 to help retain theimplant 10 against the vertebra 80. As can be appreciated, such anarrangement is merely one example of how the second portion 44 may beshaped to retain the implant 10 when the first portion 42 is securedrelative to the vertebra 80. A wide variety of other shapes are possiblefor both the second portion 44 and opening 28, as long as the secondportion 44 has a portion with a radial dimension larger than thesmallest dimension of the opening 28. Additionally, because the secondportion 44 interacts with the implant 10 rather than the cortical bone82 and cancellous bone 84, it need not be formed from the same materialas the first portion 42. The second portion 44 may instead be formedfrom a different biocompatible material designed to reduce cost andwithstand wear.

A method of securing the implant 10 to the vertebra 80 with theattachment device 40 will now be described. The hole 86 is first formedin the vertebra 80 by drilling or any other suitable technique. Theimplant 10 is then positioned relative to the vertebra 80 and one of theopenings 28 is aligned with the hole 86 so that the attachment device 40may be inserted therethrough to secure the implant 10. Due to its highlyporous nature, it is desirable to insert the first portion 42 throughthe opening 28 in the implant 10 and into the hole 86 in the vertebra 80without a significant amount of contact between the outer surface 64 andthe cortical bone 82 and cancellous bone 84. If the outer surface 64scrapes against the cortical bone 82 or cancellous bone 84 as it isinserted into the hole 86, the pores may become clogged or their spongystructure may otherwise become compromised, which diminishes the abilityof the first portion 42 to allow bone ingrowth.

Advantageously, the hole 86 may be formed with a shape thatsubstantially corresponds to the shape of the first portion 42. FIGS. 5Aand 5B schematically illustrate the hole 86 and first portion 42 in thecancellous bone 84. The hole 86 has a substantially elliptical shapewith a first dimension D1 along the major axis 46 approximately equal tothe first dimension L1 of the first portion 42 and a second dimension D2along the minor axis 48 slightly larger than the second dimension L2 ofthe first portion 42 (but still smaller than the dimension L1 along themajor axis 46). As a result of this arrangement, the first portion 42cannot be inserted into the hole 86 until the first dimension L1 isaligned along the major axis 46 and the second dimension L2 is alignedalong the minor axis 48. Additionally, the second portion 44 may have across-sectional dimension equal to or greater than the second dimensionD2 so that it does not extend through the implant 10 and into the hole86. Spaces 88, 90 maintained between outer surface 64 and hole 86 onopposite sides of major axis 46 help protect the porous structure of thefirst portion 42 from becoming clogged or compromised from contact withthe cancellous bone 84.

The hole 86 may be designed to create a slight interference fit with afirst bone-engaging surface 92 and a second bone-engaging surface 94 ofthe first portion 42 along the major axis 46 to initially secure theattachment device 40 relative to the vertebra 80. Only the firstbone-engaging surface 92 and second bone-engaging surface 94 contact thecancellous bone 84 such that the effect of this contact on the porousstructure of the second portion 44 is limited to small, localized areas.Once the first portion 42 is positioned within the hole 86, a surgeonmay then rotate the attachment device 40 relative to the vertebra 80 toincrease the amount of interference between the hole 86 and the firstportion 42. This rotation will typically be accomplished by using a toolconfigured to grip the fastening section 54 of the second portion 44.

As shown in FIG. 5B, when the attachment device 40 is rotatedapproximately 90°, the first bone-engaging surface 92 and secondbone-engaging surface 94 become substantially aligned along the minoraxis 48 and the spaces 88, 90 become aligned along the major axis 46.Because the second dimension D2 of the hole 86 is less than the firstdimension D1, the first portion 42 is forced into further compression tosecure the attachment device 40. Upon rotation, the first portion 42 maydeform the cancellous bone 84. And because the first dimension D1 of thehole 86 is larger than the second dimension D2, the spaces 88, 90increase in size so as to define larger voids between the first portion42 and cancellous bone 84.

In some embodiments, the second portion 44 rotates with the firstportion 42 when securing the attachment device 40. In other embodiments,the first portion 42 may be rotatingly attached to the second portion 44so that the second portion need not rotate with the first portion 42.For example, an instrument (not shown) designed to engage the firstportion 42 may be inserted through the axial bore 60 of the secondportion 44. Once engaged with the first portion 42, the instrument maybe then be rotated to cause the first portion 42 to rotate relative tothe second portion 44 and to secure the attachment device 40 within thehole 86.

Once the first portion 42 is inserted into the hole 86 and before,during, or after the rotation of the attachment device 40, the spaces88, 90 may be filled with a material configured to promote the growth ofbone into the porous structure of the first portion 42. For example,morselized bone or bone morphogenetic protein (BMP) may be packed intothe spaces 88, 90. Advantageously, the morselized bone or BMP may bedelivered to the spaces 88, 90 through the axial bore 60 and inner bore62. The surgeon's ability to place this material through the inner bore62 to the spaces 88, 90 improves following the rotation of the firstportion 42 as the spaces 88, 90 increase in size to define larger voids.

In alternative embodiments, the first portion 42 does not need to berotated to secure the attachment device 40 to a hole in a bone. Forexample, as shown in FIG. 6, the first bone-engaging surface 92 andsecond bone-engaging surface 94 may be designed to create aninterference fit with a hole 96 in a bone 98 upon inserting the firstportion 42 into the hole 96. The remainder of the outer surface 64 ofthe first portion 42 is not in engagement with the bone 98, and bonegrowth-promoting material may still be delivered through the inner bore62 without obstruction. Thus, in such an embodiment, the hole 96 may beany shape that allows for the creation of the interference fit.

Even though the first portion 42 may not need to be rotated in FIG. 6 tosecure the attachment device 40 within the hole 96, there may beinstances when such rotation facilitates insertion of the first portion42 into the hole 96. For example, in some embodiments, the hole 96 mayhave a circular cross-sectional configuration and the firstbone-engaging surface 92 and/or second bone-engaging surface 94 mayinclude threads (not shown). After aligning the first portion 42 withthe hole 96 and initially engaging the bone 98, the first portion 42 maybe rotated and driven further into the hole 96 by the threads to securethe attachment device 40. The first bone-engaging surface 92 and secondbone-engaging surface 94 are the only portions of the outer surface 64that come into contact with the bone, thus leaving the remaining porousmaterial of the first portion 42 unclogged and free to facilitate bonein-growth.

Due to the highly porous nature of the material forming the firstportion 42, bone is able to rapidly grow into the first portion 42 tofuse the attachment device 40 to the vertebra 80. In one embodiment, thefirst portion 42 is comprised of a structural biomaterial that is atleast 70% porous. In another embodiment, the first portion 42 iscomprised of a structural biomaterial, such as Trabecular Metal™material, that is at least 80% porous. The bone-like physical andmechanical properties of Trabecular Metal™ material contribute toextensive bone infiltration so that the attachment device 40 is stronglyattached to the vertebra 80.

FIG. 7 illustrates an attachment device 100 according to an alternativeembodiment of the invention. Like the attachment device 40, theattachment device 100 includes a first portion 102 and a second portion104, with at least the first portion 102 being formed from a materialhaving a degree of porosity that approaches that of natural bone. Thesecond portion 104 may also be formed from a material that has a degreeof porosity that approaches that of natural bone. For example, in oneembodiment, both the first portion 102 and second portion 104 may beconstructed from Trabecular Metal™ material. In another embodiment, thefirst portion 104 may be constructed from a first material with a firstporosity and the second portion 102 may be constructed from a secondmaterial with a second porosity less than the first porosity.

The second portion 104 includes a flange section 106 that operates inthe same manner as the flange section 52. If desired, the second portion104 may also be provided with a fastening section (not shown) thatoperates in the same manner as the fastening section 54. Accordingly,reference can be made to the description of the embodiment in FIGS. 2-4for an understanding of the second portion 104. Although a sectionsimilar to the first section 50 is not provided on the second portion104, it will be appreciated that the second portion 104 may be formedwith such a section if desired.

The first portion 102 is generally cylindrical in nature and includes amain body section 110 having an outer surface 112 and a bottom section114. One or more grooves 116 may be provided in the outer surface 112 sothat groove surfaces 118 are recessed relative to the outer surface 112.Such an arrangement protects the groove surfaces 118 from contact withbone when the attachment device 100 is inserted into a hole in the bone.For example, after the attachment device 100 is inserted into a hole inthe bone, the network of pores extending from the groove surfaces 118remains unclogged and intact due to the recessed configuration of thegroove surfaces 118. As a result, bone may rapidly grow into the firstportion 102 to fuse the attachment device 100 to the bone.Advantageously, the grooves 116 may be packed with bone growth-promotingmaterial, such as morselized bone or BMP, prior to being inserted into ahole in a bone.

FIG. 8 illustrates a cross-section of the attachment device 100 wheninserted into a hole 122 extending through an outer layer of corticalbone 120. The outer surface 112 defines a plurality of bone-engagingsurfaces 115 in contact with the cortical bone 82. Conversely, thegrooves 116 are not in contact with the cortical bone 120 allowing forbone in-growth or enabling the grooves 116 to be filled with bonegrowth-promoting materials. Thus, in this embodiment, the grooves 116collectively define a bone in-growth portion of the attachment device 40and the remainder of the attachment device 40, including thebone-engaging surfaces 115, defines an interference fit portion 126.

FIG. 9 illustrates an attachment device 200 according to yet anotherembodiment of the invention. Because the attachment device 200 issubstantially similar to the attachment device 100, like referencenumbers are used to refer to like structure and only the differencesbetween the two embodiments will be discussed below.

In particular, the attachment device 200 further includes a bore 202extending through the second portion 104 and into the first portion 102.Instead of or in addition to including the grooves 116, one or morechannels 204 are provided along at least a portion of the first portion102. Each channel 204 extends from the outer surface 112 to the bore202. As a result, morselized bone, BMP, or other material designed topromote bone growth may be delivered to the channels 204 through thebore 202 before, during, or after the attachment device 200 is insertedinto a hold in a bone. If desired, the bore 202 may extend completelythrough both the main body section 110 and bottom section 114 of thefirst portion 102.

While the invention has been illustrated by the description of one ormore embodiments thereof, and while the embodiments have been describedin considerable detail, they are not intended to restrict or in any waylimit the scope of the appended claims to such detail. Additionaladvantages and modifications will readily appear to those skilled in theart. For example, the first portion 42 may alternatively have a circularcross-sectional profile when viewed in a plane perpendicular to the axis45. Additionally, the attachment device 40 need not be symmetrical aboutthe axis 45 as it is shown. In other embodiments, the implant can be aplate, such as a cervical plate, configured for attachment to avertebral body. One exemplary plate is shown in U.S. Pat. No. 6,890,335,the disclosure of which is fully incorporated herein by reference. Theinvention in its broader aspects is therefore not limited to thespecific details, representative apparatus and methods and illustrativeexamples shown and described. Accordingly, departures may be made fromsuch details without departing from the scope or spirit of the generalinventive concept.

1. A system for the treatment of a spine, the system comprising: animplant configured to be secured to a portion of a patient's bone, thebone having a hole greater in a first dimension than in a seconddimension; and an attachment device having: a rigid first portion havinga cross-section sized for insertion into the hole in the bone, thecross-section along a length of the first portion having a firstdimension greater than a second dimension, the first portion comprisinga biocompatible material defined by a network of interconnected poresconfigured to promote bone growth into the first portion, wherein thebiocompatible material comprises porous tantalum, wherein the firstportion has a substantially elliptical cross-sectional profile; and asecond portion configured to be received in an opening of the implant;wherein the first portion of the attachment device is configured to berotated in the hole in the bone to a position that restricts removal ofthe attachment device from the hole.
 2. The system of claim 1 whereinthe second portion has a substantially circular cross-sectional profile.3. The system of claim 1 wherein the second portion includes a firstsection having a first radial dimension and a flange section having asecond radial dimension larger than the first radial dimension.
 4. Thesystem of claim 3 wherein the second portion further includes afastening section extending from the flange section, the fasteningsection including a plurality of straight edges arranged in a hexagonalconfiguration.
 5. The system of claim 1 wherein the second portionincludes an axial bore extending therethrough.
 6. The system of claim 5wherein the first portion includes an outer surface and an inner borecommunicating with the axial bore of the second portion, the inner boreof the first portion extending from the axial bore to a first locationon the outer surface.
 7. The system of claim 6 wherein the inner bore ofthe first portion extends from the axial bore of the second portion to asecond location on the outer surface.
 8. The system of claim 7 whereinthe inner bore of the first portion has an inverted y-shapedconfiguration with first and second branches extending to the respectivefirst and second locations on the outer surface.
 9. The system of claim1 wherein the implant is a plate for attachment to a vertebral body. 10.The system of claim 1 wherein the first portion includes an inner boreextending therethrough, an outer surface, and a plurality of channelseach extending from the outer surface to the inner bore, the channelsproviding fluid communication from the inner bore to the bone for thedelivery of a bone growth promoting material.
 11. A system for thetreatment of a spine, the system comprising: an implant for attachmentto a patient's bone; and an attachment device having: a rigid firstportion comprising a biocompatible material defined by a network ofinterconnected pores, the first portion having a substantiallyelliptical cross-sectional profile, being sized for insertion into ahole in the patient's bone, and having a bone in-growth portion topromote bone growth into the first portion and an interference fitportion to engage the bone, the bone in-growth portion including anaxial bore and one or more branching bores extending from the axial boreto an outer surface of the first portion, wherein the bores are open toallow bone in-growth when the first portion is inserted into the hole inthe bone; and a second portion configured to be received in an openingof the implant for securing the implant to the patient.
 12. The systemof claim 11 wherein the biocompatible material has a degree of porositythat approaches that of the bone.
 13. The system of claim 11 wherein thebiocompatible material comprises porous tantalum.
 14. A method ofsecuring an implant to a bone of a patient with an attachment device,the implant having an opening, the attachment device having a rigidfirst portion and a second portion coupled to the first portion, thefirst portion having a length and an elliptical cross-sectionalconfiguration along its length with a first dimension and a seconddimension less than the first dimension, and the first portion beingcomprised of a biocompatible material defined by a network ofinterconnected pores configured to promote bone growth into the firstportion, the method comprising: forming a hole in the bone with anelliptical configuration having a minor axis, a major axis, and firstdimension along the major axis approximately equal to the firstdimension of the first portion; positioning the implant relative to thebone so that the opening of the implant is in communication with thehole in the bone; and inserting the first portion of the attachmentdevice through the opening of the implant and into the hole of the bonewith the first dimension aligned with the major axis of the hole and thesecond dimension aligned with the minor axis of the hole so that thesecond portion is received in the opening of the implant.
 15. The methodof claim 14 wherein the hole in the bone and the first portion areformed with matching elliptical configurations.
 16. The method of claim14, further comprising, after inserting: rotating the attachment memberrelative to the hole in the bone so that the first dimension of thefirst portion is substantially aligned with the minor axis of the holeand the second dimension of the first portion is substantially alignedwith the major axis of the hole.
 17. The method of claim 16 whereinrotating the attachment member further comprises rotating the firstportion relative to the second portion.
 18. The method of claim 14wherein the second portion further includes an axial bore extendingtherethrough and the first portion further includes an inner boreextending therethrough and communicating with the axial bore, the methodfurther comprising: inserting bone growth material through the axialbore of the second portion and through the inner bore of the firstportion.
 19. The method of claim 18 wherein inserting the bone growthmaterial further comprises: inserting morselized bone through the axialbore of the second portion and through the inner bore of the firstportion.
 20. The method of claim 18 wherein inserting the bone growthmaterial further comprises: inserting bone morphogenetic protein throughthe axial bore of the second portion and through the inner bore of thefirst portion.